Abstract
Annual Review of Biomedical Engineering
Vol. 8:
455-498
(Volume publication date August 2006)
(doi:10.1146/annurev.bioeng.8.061505.095721)
First published online as a Review in Advance on April 3, 2006BIOMECHANICAL AND MOLECULAR REGULATION OF BONE REMODELING Alexander G. Robling,1 Alesha B. Castillo,1,2 and Charles H. Turner2,31Departments of Anatomy and Cell Biology, 2Biomedical Engineering, and 3Orthopaedic Surgery, Indiana University Purdue University, Indianapolis, Indiana 46202; email: turnerch@iupui.edu Abstract Bone is a dynamic tissue that is constantly renewed. The cell populations that participate in this process—the osteoblasts and osteoclasts—are derived from different progenitor pools that are under distinct molecular control mechanisms. Together, these cells form temporary anatomical structures, called basic multicellular units, that execute bone remodeling. A number of stimuli affect bone turnover, including hormones, cytokines, and mechanical stimuli. All of these factors affect the amount and quality of the tissue produced. Mechanical loading is a particularly potent stimulus for bone cells, which improves bone strength and inhibits bone loss with age. Like other materials, bone accumulates damage from loading, but, unlike engineering materials, bone is capable of self-repair. The molecular mechanisms by which bone adapts to loading and repairs damage are starting to become clear. Many of these processes have implications for bone health, disease, and the feasibility of living in weightless environments (e.g., spaceflight). Terms and Definitions Basic multicellular unit (BMU): temporary anatomic structure comprising osteoclasts and osteoblasts that replace older packets of bone with new bone tissue Disuse: absence of the normal peak strains typical for a region of bone tissue; can be induced by immobilization, bedrest, or spaceflight Mechanotransduction: the conversion of a physical force into a biochemical/cellular response Microdamage: irreversible fatigue damage created in bone as a result of loading-induced stress risers, manifest as microscopic cracks, microfractures, and diffuse damage Osteoblast: bone cell of mesenchymal origin that secretes unmineralized bone matrix (osteoid), which eventually mineralizes to yield mature bone Osteoclast: bone cell of hematopoetic origin that resorbs bone by secretion of acid and proteases Osteocyte: terminally differentiated osteoblast that has become entombed in the bone matrix it once elaborated Responsiveness of human bone marrow stromal cells to shear stress Journal of Tissue Engineering and Regenerative Medicine 3(4):302-309 (2009) Expression, signaling, and function of P2X7 receptors in bone Purinergic Signalling 5(2):205-221 (2009) New Suggestions for the Mechanical Control of Bone Remodeling Calcified Tissue International (2009) Effects of extracts of oxyntic mucosa in rat on the biological activity of osteoblasts Osteoporosis International (2009) Comparison of Dentoalveolar Morphology in WT and P2X7R KO Mice for the Development of Biomechanical Orthodontic Models The Anatomical Record: Advances in Integrative Anatomy and Evolutionary Biology 292(2):292-298 (2009)
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